KR101532234B1 - Floating platform for operation in regions exposed to extreme weather conditions - Google Patents

Abstract

The floating platform for exploration or production of hydrocarbons has a semi-submersible main platform 2, which is loaded as a process and / or drilling rig on the upper surface 7 and is designed as a basically cylindrical vertical bottom. The main platform 2 is provided with a central vertical shaft 8 which has at its lower end an anchoring line 10, risers 14 and 15 and loading equipment for umbilicals The anchoring buoy 3 is received and releasably locked.

Floating Platform, Main Platform, Vertical Shaft, Anchoring Buoy, Riser, Winch

Description

FLOATING PLATFORM FOR OPERATION IN REGIONS EXPOSED TO EXTREME WEATHER CONDITIONS FOR WORKING IN ENVIRONMENTAL CLIMATE CONDITIONS

The present invention relates to a floating platform for exploration and production of hydrocarbons at sea, comprising a floating platform having a semi-submerged main platform, which is designed as a vertically cylindrical basically floor with a process and / Lt; / RTI > platform.

One platform designed as described above is known from Norway Patent No. 319971. By designing the platform as a cylindrical platform body, considerable reductions in pitching and rolling motion are obtained. Such a platform also has a large storage capacity for production or drilling equipment and a large storage capacity for oil, fuel and the like. Such a platform does not differ due to its orientation to the effects of the surrounding environment, and thus can be anchored by a simple fixed anchoring system. Also, a riser can be directly connected to the receiving system on the platform without the need for a swivel transference or the like.

For operation in the Arctic, where there is a risk of iceberg, one requirement is that the floating platform must have the potential to separate both the anchoring system and the riser. For example, when working in areas with extreme low climatic conditions, such as those exposed to hurricanes, the ability to remove floating devices significantly reduces the requirements for anchoring systems, resulting in significant benefits .

A disadvantage of conventional separation processes in which anchoring lines and risers are separated separately in the production of hydrocarbons is that there is a loss of time and production is discontinued. Also, the equipment that needs to be detached becomes expensive to allow for possible leaks as well as towing at sea. The separation and subsequent connection of the anchoring lines and / or risers may involve production discontinuation of the production apparatus over several weeks. The connection will generally require that the ancillary line and the secondary vessel be joined to lift the riser. Therefore, this connection will be sensitive to weather conditions.

It is an object of the present invention to provide a platform that can be used in areas exposed to extreme climates or where ice drifts and icebergs occur.

According to the invention, the main platform is provided with a central vertical shaft, which at its lower end has an anchoring line, a riser and an umbilical < RTI ID = 0.0 > And an anchoring part for loading the fastening device is received in such a manner as to be releasably locked.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below with reference to the accompanying drawings, in which: Fig.

1 shows a main platform and an anchoring part connected together;

Figure 2 shows how the anchoring buoy is raised to the main platform by a chain winch;

Figure 3 shows a first embodiment of an anchoring portion to which a flexible riser is connected;

Fig. 4 shows a second embodiment of an anchoring portion to which a steel riser is connected;

5 shows an installation plan view of an anchoring line connected to an anchoring portion;

Figure 6 shows an anchoring portion dropped to the free floating position after detachment;

Figure 7 shows an elevated tow line extending from the anchoring portion to float on the water surface.

1 and 2, the platform structure 1 of the illustrated embodiment according to the present invention comprises an anchoring unit consisting of a main platform 2 and a submerged anchoring portion 3. The main platform 2 is designed as a vertically cylindrical body, basically flat at the beginning of the description, similar to that described above. The main platform 2 may have a circular or polygonal cross-section.

Contrary to previously known platforms, the cylindrical body of the present invention has a central vertical shaft 8, which houses the anchoring portion 3 at its lower end and is releasably locked . The main platform has double walls and possibly double floors, while the double walls and double floors are used as ballast tanks (4). The ballast tanks (4) are divided into a sufficient number of tanks in order to ensure that the stability against damage is ensured. Inside the ballast tank, a storage tank 5 for storing hydrocarbons is arranged. An engine room, various tanks, a cofferdam, and the like are located below the accommodation area 18 of the main deck 7. Equipment for the production of oil and gas, drilling equipment and various auxiliary systems are located as modules 6 on the main deck.

As shown in Figures 1 and 2, a winch 9 is disposed at the top of the shaft 8 to draw the anchoring portion 3 from the dive position to the connecting position in the shaft 8. The anchoring portion has an at least partially conical shape to be accommodated in the corresponding conical portion of the lower portion of the shaft 8. When the anchoring buoy 3 is located in the correct position in the shaft 8, the anchoring buoy 3 is tightly locked by a mechanical locking means (not shown). The winch 9 may also be used for connection of the anchoring line (anchor chain) 10 of the platform, pre-stressing and post-tensioning. On the main platform there is also a coupling manifold for good flow and oil and gas delivery. The transfer hose will be installed between the coupling manifold and the riser fastening device 20 disposed on the anchoring portion.

The main platform 2 does not have a propulsion system and can be a driven device which must be towed by the auxiliary vessel in case it has to approach and depart from the connection position or has to be moved away from its current position. The main platform may also have a propeller (thruster) 11 that imparts performance to the main platform itself without any support from the secondary. The main platform can move itself by avoiding bad weather or icebergs, navigate back to the original device and be self-coupled to the anchoring buoy 3.

The anchoring buoy (3) is a large buoyant tank. This buoyant tank is divided into an adequate number of cells to ensure that any damage will not have a dramatic effect. At the outer edge of the anchoring buoy 3, a fairlead 12 for fastening the anchor chain 10 is located. The anchor chain 10 extends from the plow 12 to the chain lock 13 at the top of the anchoring portion. The chain lock 13 will support all of the force from the anchor chain 10 in both cases when the anchoring buoy floats freely and when it is connected to the main platform 2. Risers 14, 15 and umbilical will be connected to the anchoring buoy 3. If a flexible riser 14 is used at normal water depths, an I-tube or J-tube will be deployed through the hull extending from the bottom to the top. The riser 14 may then be pulled in and locked in place on the upper edge of the buoy. A safety valve or the like will be disposed along with the fastening device 20 for connection of the transfer hose or the like. At the bottom of the I-tube or J-tube, a bellmouth or lock can be placed for fastening the bend stiffener. When a steel catenary riser (SCR) 15 is used, an opening 25 is arranged in the center of the buoy, and a riser string receiving deck will be placed in this opening 25. The riser will then be hung on the flexible joint fastened to this riser string acceptance deck. A safety valve, a coupling flange, etc., will be placed on the riser string receiving deck. With this configuration, the steerer will hang freely and face the seabed. A similar suspension method can also be used to freely tie the flexible riser 14. [ Then the flexible joint at the top will not be needed.

When installing the platform structure 1, the main platform 2 and the anchoring part 3 will be interconnected by mechanical locking means. The traction / adjustment of the anchoring line 10 and the tensioning of the anchoring line 10 will be the same as in conventional devices. After traction of the anchoring line 10, the anchoring line 10 will be locked by the chain lock 13, which is disposed at the top of the anchoring portion 3. After locking of the anchoring line / anchor chain 10, the chain of lengths pulled up onto the deck will be placed in the chain locker 16 located at the top of the anchoring buoy. An elevated traction line 17 will be mounted at the end of some chains. The number of ascending traction lines 17 depends on how the anchoring lines 10 are disposed. In the configuration shown in Fig. 5, three rising tow lines 17 will be used. That is, one rising tow line 17 will be used for each group of anchoring lines 10. The ascending traction line 17 can be used to ascend the ascending traction line 17 after the elevated traction line 17 with the buoyancy element in the remote remotely operated vehicle (ROV) Or at least one line 23 may be arranged to be lifted up with a floating element 22 floating on the surface of the water.

Traction and connection of risers, umbilicals, etc., will also be performed by the anchoring buoy 3 connected. After locking the risers 14 and 15, the connecting hose and cable between the top of the riser / cable and the manifold device on the main platform 2 can be mounted in place. After the connection of the anchoring line 10 and the risers 14, 15, the platform structure 1 is ready for operation.

As described above, the anchoring portion 3 in the connection position is locked to the main platform 2 by mechanical locking means. Before the separation can be carried out, all connection hoses and cables between the main platform 2 and the anchoring part 3 must be separated. When all such connection hoses and cables have been disconnected, the anchoring part can be separated by opening the mechanical locking means. The anchoring portion is loaded with the ballast load so as to find an equilibrium point of a predetermined depth (D) below the water surface (24). The anchoring buoy 3 will now float in a position where it receives a very small amount of load from the wave. In addition, the risk of collision with ships and with icebergs will be minimized.

When connecting the anchoring buoy 3 to the main platform 2, the main platform 2 will be in the correct position on the anchoring buoy 3, with or without assistance of the auxiliary ship. Pulls upward the towing line 7 where the remote unmanned submersible (ROV) is located within the shaft 8 of the main platform 2. The ascending traction line 17 is connected to a chain winch 9 used to pull up the end of the anchor chain 10 disposed in the chain locker 16 at the top of the anchoring portion 3, Is positioned on the chain winch (9). Towing is carried out by pulling the anchoring buoy 3 together with all the risers, umbilicals, cables and the like that the chain winch 9 extends down to the sea floor and is connected to the sea floor. When the anchoring buoy 3 is in the correct position inside the shaft 8 of the main platform 2, the anchoring buoy 3 is locked by the mechanical locking means. When the coupling hose, cable or the like of the main platform 2 is connected to the anchoring portion 3, production can be resumed.

Alternatively, the ascending tow line 17 will have floating buoys 21, 22 that can be ejected, for example, by sonar signals, or float on the surface and can be towed up in a conventional manner. If a configuration with floating lifting tow lines is used, one line must be placed from the shaft 8 to the side of the main platform 2. In this case, the floating lifting tow line 23 is pulled up from the side of the main platform 2 and connected to the lifting pull line 17. The buoyancy elements 21 and 22 are separated and the lines connected to each other are dropped again into the water. The ascending tow line 17 can now be pulled up through the shaft 8 and connected to the chain winch 9. Other lifting operations and connections will be the same as when using a remote unmanned docking point (ROV).

If such an arrangement is to be located on the deck 7 of the platform when the platform structure 1 is to be equipped with a device for oil drilling, such a device will have a vertical opening (moon pool ), A hollow cavity facility at the center of the deep-sea excavation line; In this case, it may be optimal to use a part of the loading tank 5 as a doorpane. If you use an "internal" doorway, the drill risers, etc. will be protected against ice in the exposed areas. In addition, if the oil leakage in the interior of the frame is also cut off and removed in a simple manner.

Alternatively, the drilling rig may be located in a cantilever platform on the side of the main platform 2. [ In the case of drilling, the anchoring line can be adjusted to maintain the correct position of the platform when the climate impact fluctuates. If the platform is equipped with a thruster 11, this thruster 11 may also be used to maintain an optimal position during drilling.

When connecting and separating the anchoring buoy 3, the drilling rig is not involved. The drilling risers, etc. will only be connected after the anchoring buoy is in the locked position. When separating the anchoring buoy 3, the separating riser must be separated from the seabed together with the relevant valve or the like before being separated from the anchoring portion 3, and preferably be lifted up and loaded.

Claims (9)

As a floating platform for exploration drilling and production of hydrocarbons at sea, A semi-submersible main platform, loaded on the upper side with process equipment or drilling equipment or both process equipment and drilling equipment, and designed as basically a vertical flat cylinder; Wherein the main platform is provided with a central vertical shaft and the central vertical shaft has a shape corresponding to the shape of at least a portion of the anchoring portion at the lower end of the anchoring portion and an anchoring portion for mounting the anchoring lines for the riser and the umbilical. The anchoring buoy being configured to be at least partially received within a central vertical shaft; And A releasable locking means for connecting and disconnecting the anchoring portion with the main platform, wherein the anchoring portion is rigidly and releasably connected to the main platform by the locking means when the anchoring portion is in the coupling position in the shaft and the locking means is released Wherein the anchoring portion is configured to be detached from the main platform. 2. The floating platform of claim 1, wherein the anchoring portion has an at least partially conical shape to be received within a corresponding conical portion of the lower portion of the shaft of the main platform. 3. Floating platform according to claim 1 or 2, characterized in that the anchoring part comprises a chain stopper and a cutter located along the periphery of the anchoring part. 3. Floating platform according to claim 1 or 2, characterized in that the anchoring part has a fastening device of a flexible riser or a steel riser in the central opening of the anchoring part. 3. The anchorage according to claim 1 or 2, characterized in that the anchoring portion is divided into a plurality of ballast tanks which can be partially filled with a ballast material to impart an appropriate depth (D) in water to the anchoring portion after separation Floating platform. 3. Floating platform according to claim 1 or 2, characterized in that the anchoring part has a line construction which makes it possible to connect the end of the anchor chain to the winch on the main platform. 3. Floating platform according to claim 1 or 2, characterized in that the anchoring portion can be pulled into the shaft of the main platform using a winch used for traction and tensioning of the anchor chain. 3. Floating platform according to claim 1 or 2, characterized in that the main platform has a vertical opening (platform) in the platform hull for performing drilling or other borehole maintenance. The floating platform of claim 1, wherein the main platform has a cantilever platform for supporting equipment for performing drilling or other borehole maintenance.

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